Auber Instruments SYL-2342P 사용 설명서 - 페이지 5
{카테고리_이름} Auber Instruments SYL-2342P에 대한 사용 설명서을 온라인으로 검색하거나 PDF를 다운로드하세요. Auber Instruments SYL-2342P 8 페이지. Pid temperature controller
AUBER INSTRUMENTS
PV
103
SV+Hy
100
SV
SV-Hy
97
Relay On
Figure 5. On/off control mode.
4.5.3. Manual mode
Manual mode allows the user to control the output as a percentage of the total
heater power. It is like a dial on a stove. The output is independent of the
temperature sensor reading. One application example is controlling the
strength of boiling during beer brewing. You can use the manual mode to
control the boiling so that it will not boil over to make a mess. The manual
mode can be switched from PID mode but not from on/off mode. This controller
offers a "bumpless" switch from the PID to manual mode. If the controller
outputs 75% of power at PID mode, the controller will stay at that power level
when transitioned into the manual mode, until it is adjusted manually. See
Figure 3 for how to switch the display mode. The Manual control is initially
disabled (A-M = 2). To activate manual control, please make sure At = 3
(section 4.4.3) and A-M = 0 or 1 (section 4.16). If you are currently in
ON/OFF mode (At = 0), you will not be able to use manual mode.
4.6 Cycle time "t"
Cycle time is the time period (in seconds) that the controller uses to calculate
its output. For example, when t = 20, if the controller decides output should be
10%, the heater will be on 2 second and off 18 seconds for every 20 seconds.
For relay or contactor output, it should be set longer to prevent contacts from
wearing out too soon. Normally it is set to 20~40 seconds.
4.7 Input selection code for "Sn"
Please see Table 3 for the acceptable sensor type and its range.
Table 3. Code for Sn and its range.
Sn
Input device
0
K (thermocouple)
1
S (thermocouple)
2
WRe (5/26)(thermocouple)
3
T (thermocouple)
4
E (thermocouple)
5
J (thermocouple)
6
B (thermocouple)
7
N (thermocouple)
20
Cu50 (RTD)
21
Pt100 (RTD)
26
0 ~ 80 Ω
27
0 ~ 400 Ω
28
0 ~ 20 mV
29
0 ~ 100 mV
30
0 ~ 60 mV
31
0 ~ 1000 mV
200 ~ 1000 mV,
32
4-20 mA (w/ 50Ω Resistor)
1 ~ 5 V
33
4~20 mA (w/ 250Ω Resistor)
34
0 ~ 5 V
35
-20 ~ +20 mV
36
-100 ~ +100 mV
37
-5 ~ +5V
2021.06
When heating, At=0
If PV (SV-Hy), relay on
If PV (SV+Hy), relay off
(SV=100, Hy=3)
Display range
Display range
Wiring
(° C)
(° F)
-50~+1300
-58~2372
-50~+1700
-58~3092
0~2300
32~4172
-200~350
-328~662
0~800
32~1472
0~1000
32~1832
0~1800
32~3272
0~1300
32~2372
-50~+150
-58~302
-200~+600
-328~1112
-1999~+9999 Defined by user
with P-SL and P-SH
4.8 Decimal point setting "dP"
1) In case of thermocouple or RTD input, dP is used to define temperature
display resolution.
dP = 0, temperature display resolution is 1 ºC (ºF).
dP = 1, temperature display resolution is 0.1 ºC . The 0.1 degree resolution is
only available for Celsius display. The temperature will be displayed at the
resolution of 0.1 ºC for input below 1000 ºC and 1 ºC for input over 1000 ºC.
2) For linear input devices (voltage, current or resistance input, Sn = 26-37).
Table 4. dP parameter setting.
dP Value
Display format
4.9 Limiting the control range, "P-SH" and "P-SL"
1) For temperature sensor input, the "P-SH" and "P-SL" values define the set
value range. P-SL is the low limit, and P-SH is the high limit. For example,
sometimes you may want to limit the temperature setting range so that the
operator can't set a very high temperature by accident. If you set the P-SL =
100 and P-SH = 130, operator will only be able to set the temperature between
100 and 130.
2) For linear input devices, "P-SH" and "P-SL" are used to define the display
span. e.g. If the input is 0-5V. P-SL is the value to be displayed at 0V and P-SH
is the value at 5V.
4.10 Input offset "Pb"
Pb is used to set an input offset to compensate the error produced by the
sensor or input signal itself. For example, if the controller displays 5ºC when
probe is in ice/water mixture, setting Pb = -5, will make the controller display
0ºC.
4.11 Output definition "OP-A"
This parameter is not used for this model. It should not be changed.
4.12 Output range limits "OUTL" and "OUTH"
OUTL and OUTH allow you set the output range low and high limit.
OUTL is a feature for the systems that need to have a minimum amount of
power as long as the controller is powered. e.g. If OUTL = 20, the controller
will maintain a minimum of 20% power output even when input sensor failed.
Pins
4, 5
OUTH can be used when you have an overpowered heater to control a small
4, 5
subject. e.g. If you set the OUTH = 50, the 5000 watt heater will be used as
4, 5
2500W heater (50%) even when the PID wants to send 100% output.
4, 5
4, 5
4.13 Alarm output definition "AL-P"
4, 5
Parameter "AL-P" may be configured in the range of 0 to 31. It is used to define
4, 5
which alarms ("ALM1", "ALM2", "Hy-1" and "Hy-2") is output to AL1 or AL2. Its
4, 5
function is determined by the following formula:
3, 4, 5
AL-P = AX1 + BX2 + CX4 + DX8 + EX16
3, 4, 5
3, 4, 5
If A = 0, then AL2 is activated when Process high alarm occurs.
3, 4, 5
If A = 1, then AL1 is activated when Process high alarm occurs.
4, 5
If B = 0, then AL2 is activated when Process low alarm occurs.
4, 5
If B = 1, then AL1 is activated when Process low alarm occurs.
4, 5
If C = 0, then AL2 is activated when Deviation high alarm occurs.
4, 5
If C = 1, then AL1 is activated when Deviation high alarm occurs.
4, 5
If D = 0, then AL2 is activated when Deviation low alarm occurs.
If D = 1, then AL1 is activated when Deviation low alarm occurs.
2, 5
If E = 0, then alarm types, such as "ALM1" and "ALM2" will be displayed
2, 5
alternatively in the lower display window when the alarms are on. This makes it
4, 5
easier to determine which alarms are on.
4, 5
If E = 1, the alarm will not be displayed in the lower display window (except for
2, 5
"orAL"). Generally, this setting is used when the alarm output is used for control
purposes.
For example, in order to activate AL1 when a Process high alarm occurs,
trigger AL2 by a Process low alarm, Deviation high alarm, or Deviation low
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